Utility materials incorporating a microparticle matrix formed with a setting agent

ABSTRACT

A composition, utility material, and method of making a utility material is disclosed. A composition having an improved setting time may include a plurality of microparticles mixed with a sodium silicate binder and an isocyanate setting agent, where the microparticle composition has a setting time of less than or equal to one hour. A utility material may be a wallboard that includes the composition.

RELATED APPLICATIONS

This application is a Continuation Patent Application of U.S. patentapplication Ser. No. 12/612,675 filed on Nov. 4, 2009, which claims thebenefit of U.S. Provisional Patent Application No. 61/198,554, filed onNov. 4, 2008, the entirety of these applications is hereby incorporatedby reference.

FIELD OF THE INVENTION

The present invention relates generally to various utility and/orbuilding materials, such as wallboard, sound attenuation materials,shear panels, casting materials, etc., and more particularly to utilityand/or building materials incorporating a microparticle-based corematrix. Accordingly, the present invention involves the fields ofchemistry, manufacturing engineering, construction, and materialsscience.

BACKGROUND OF THE INVENTION AND RELATED ART

Many different types of building or utility materials, such as wallboardinsulation, blown-in insulation, acoustical or sound dampening/absorbingmaterials, etc., exist in the art. These are all designed to provide aspecific function within a structure. In addition, the composition ofingredients or components making up these utility materials variesgreatly. Although there are many different available compositions makingup the many different utility materials, relatively few of theseincorporate microparticles, such as naturally occurring cenospheres orExtendospheres™, or synthetically manufactured microparticles, intotheir makeup.

In addition, many different types of naturally occurring and artificialmicroparticles exist. Cenospheres are naturally occurring microparticlesfound in “fly ash,” which is formed during coal combustion. Cenospheresmake up a small percentage (1%-4%) of fly ash. They are hollow particleswith wall thicknesses about 10% of their diameter. Fly ash also includessmall spherical solid particles that have a much higher bulk densitythan cenospheres.

In addition, there are several artificially manufactured microparticlesused for a variety of purposes. Although such microparticles tend to bemore consistent and uniform in their makeup and structure, they alsotend to be extremely expensive and cost prohibitive for manyapplications.

Wallboard is a common utility or building material, which comes in manydifferent types, designs, and sizes. Wallboard can be configured toexhibit many different properties or characteristics, such as differentsound absorption, heat transfer and/or fire resistance properties. Byfar, the most common type of wallboard is drywall or gypsum board.Drywall comprises an inner core of gypsum, the semi-hydrous form ofcalcium sulphate (CaSO₄.½H₂O), disposed between two facing membranes,typically paper or fiberglass mats.

The most commonly used drywall is one-half-inch thick but can range fromone quarter (6.35 mm) to one inch (25 mm) in thickness. Forsoundproofing or fire resistance, two layers of drywall are sometimeslaid at right angles to one another. Drywall provides a thermalresistance, or R value, of 0.32 for three-eighths-inch board, 0.45 forhalf inch, 0.56 for five-eighths inch, and 0.83 for one-inch board. Inaddition to increased R-value, thicker drywall has a slightly higherSound Transmission Class (STC) rating.

Conventional interior walls in homes or buildings have opposing sheetsof drywall mounted on a stud frame or stud wall. In this arrangement,with the drywall panels having a ½-inch thickness, the interior wallmeasures an STC of about 33. Adding fiberglass insulation helps, butonly increases the STC to 36-39, depending upon the type and quality ofinsulation, as well as stud and screw spacing. As wallboard is typicallycomprised of several sheets or panels, the small cracks or gaps betweenpanels, or any other cracks or gaps in the wall structure are referredto as “flanking paths,” and will allow sound to transmit more freely,thus resulting in a lower overall STC rating.

SUMMARY OF THE INVENTION

Accordingly, the present invention provides a composition, utilitymaterial, and method of making a utility material. In one aspect, forexample, a composition having an improved setting time is provided. Sucha composition may include a plurality of microparticles mixed with asodium silicate binder and an isocyanate setting agent. In one aspect,the microparticle composition has a setting time of less than or equalto one hour.

In one aspect of the present invention, the plurality of microparticlesis from about 25 wt % to about 75 wt % of wet composition, the sodiumsilicate is from about 20 wt % to about 60 wt % of wet composition, andthe isocyanate setting agent is from about 2 wt % to about 10 wt % ofwet composition.

In another aspect of the present invention, the composition includes thesodium silicate binder and the isocyanate setting agent at a ratio offrom about 1:1 to about 15:1. In yet another aspect of the presentinvention, the composition includes the sodium silicate binder and theisocyanate setting agent at a ratio of from about 8:1 to about 12:1.

In still another aspect of the present invention, the plurality ofmicroparticles has a size from about 10 microns to about 1000 microns.In a further aspect of the present invention, the plurality ofmicroparticles has a size from about 10 microns to about 500 microns.

In some aspects of the present invention, the composition is a setcomposition. In a specific aspect, the composition is a curedcomposition.

In a further aspect of the present invention, the plurality ofmicroparticles contain an inert gas within an internal space.

The present invention additionally provides a utility material. In oneaspect, for example, a wallboard is provided. Such a wallboard mayinclude a first facing membrane and a second facing membrane, and a corematrix disposed between the first facing membrane and the second facingmembrane. The core matrix includes a composition as described above

The present invention additionally provides a method of making a utilitymaterial. In one aspect, for example, a method of making a wallboardhaving a setting time of less than or equal to one hour is provided.Such a method may include forming a core matrix including a mixture of aplurality of microparticles, a sodium silicate binder, and an isocyanatesetting agent, disposing the core matrix between a first facing membraneand a second facing membrane, and setting the core matrix.

In one aspect of the present invention, forming the core matrix furthercomprises forming a first mixture including a first portion of theplurality of microparticles and the sodium silicate binder, forming asecond mixture including a second portion of the plurality ofmicroparticles and the isocyanate setting agent, and mixing the firstmixture with the second mixture to form the core matrix.

In another aspect of the present invention, the method further includescoating a contact surface of at least one of the first facing membraneand the second facing membrane with a sodium silicate coating prior todisposing the core matrix therebetween.

In yet another aspect of the present invention, the core matrix is fromabout 25 wt % to about 75 wt % of wet core matrix, wherein the sodiumsilicate is from about 20 wt % to about 60 wt % of wet core matrix, andwherein the isocyanate setting agent is from about 2 wt % to about 10 wt% of wet core matrix.

In still another aspect of the present invention, the core matrixincludes the sodium silicate binder and the isocyanate setting agent ata ratio of from about 1:1 to about 15:1. In a further aspect of thepresent invention, the core matrix includes the sodium silicate binderand the isocyanate setting agent at a ratio of from about 8:1 to about12:1.

In a further aspect of the present invention, the setting time is lessthan or equal to 30 minutes. In still a further aspect of the presentinvention, setting the core matrix occurs at ambient temperature.

In some aspects of the present invention, the method includes curing thecore matrix. In a specific aspect, the method includes actively curingthe core matrix by heating. In another specific aspect, the methodincludes passively curing the core matrix.

There has thus been outlined, rather broadly, various features of theinvention so that the detailed description thereof that follows may bebetter understood, and so that the present contribution to the art maybe better appreciated. Other features of the present invention willbecome clearer from the following detailed description of the invention,taken with the accompanying claims, or may be learned by the practice ofthe invention.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention will become more fully apparent from the followingdescription and appended claims, taken in conjunction with theaccompanying drawings. Understanding that these drawings merely depictexemplary embodiments of the present invention they are, therefore, notto be considered limiting of its scope. It will be readily appreciatedthat the components of the present invention, as generally described andillustrated in the figures herein, could be arranged and designed in awide variety of different configurations. Nonetheless, the inventionwill be described and explained with additional specificity and detailthrough the use of the accompanying drawings in which:

FIG. 1 illustrates a perspective view of a wallboard building materialin accordance with one exemplary embodiment of the present invention;

FIG. 2 illustrates a detailed partial perspective view of the wallboardbuilding material of FIG. 1;

FIG. 3 illustrates a detailed partial perspective view of a wallboardbuilding material in accordance with another exemplary embodiment of thepresent invention;

FIG. 4 illustrates a perspective view of a wallboard building materialjust, prior to being installed or mounted onto a stud wall;

FIG. 5-A illustrates a detailed partial end view of a wallboard buildingmaterial having a coupling system formed therein in accordance with oneexemplary embodiment of the present invention;

FIG. 5-B illustrates a detailed partial end view of a wallboard buildingmaterial having a coupling system formed therein in accordance withanother exemplary embodiment of the present invention;

FIG. 6 illustrates a detailed perspective view of a wallboard buildingmaterial in accordance with one exemplary embodiment of the presentinvention, wherein the building material comprises a microparticle-basedcore matrix, a multi-elevational surface configuration formed in onesurface of the core matrix, and a facing sheet disposed on an opposingsurface of the core matrix;

FIG. 7-A illustrates a detailed perspective view of a wallboard buildingmaterial in accordance with another exemplary embodiment of the presentinvention, wherein the building material comprises a microparticle-basedcore matrix, a lath disposed or sandwiched within the core matrix, amulti-elevational surface configuration formed in one surface of thecore matrix, and a facing sheet disposed on an opposing surface of thecore matrix;

FIG. 7-B illustrates a detailed view of the building material of FIG.7-A;

FIG. 8 illustrates a top view of a building material in accordance withstill another exemplary embodiment of the present invention, wherein thebuilding material comprises a patterned pillow-like multi-elevationalsurface configuration formed in the exposed surface of the core matrix;

FIG. 9 illustrates a cross-sectional side view of the building materialof FIG. 8;

FIG. 10 illustrates a cross-sectional end view of the building materialof FIG. 8;

FIG. 11 illustrates a detailed side view of the building material ofFIG. 6;

FIG. 12 illustrates a detailed side view of a building material having amulti-elevational surface configuration in accordance with anotherexemplary embodiment;

FIG. 13 illustrates a detailed side view of a building material having amulti-elevational surface configuration in accordance with anotherexemplary embodiment;

FIG. 14 illustrates a cross-sectional side view of a building materialin accordance with another exemplary embodiment, wherein the buildingmaterial comprises a plurality of strategically formed and locatedcavities or voids; and

FIG. 15 illustrates a building material configured for use as afinishing material on an exterior of a structure.

DETAILED DESCRIPTION OF EXEMPLARY EMBODIMENTS

The following detailed description of exemplary embodiments of theinvention makes reference to the accompanying drawings, which form apart hereof and in which are shown, by way of illustration, exemplaryembodiments in which the invention may be practiced. While theseexemplary embodiments are described in sufficient detail to enable thoseskilled in the art to practice the invention, it should be understoodthat other embodiments may be realized and that various changes to theinvention may be made without departing from the spirit and scope of thepresent invention. Thus, the following more detailed description of theembodiments of the present invention is not intended to limit the scopeof the invention, as claimed, but is presented for purposes ofillustration only and not limitation to describe the features andcharacteristics of the present invention, to set forth the best mode ofoperation of the invention, and to sufficiently enable one skilled inthe art to practice the invention. Accordingly, the scope of the presentinvention is to be defined solely by the appended claims.

U.S. patent application Ser. No. 12/077,951 filed on Mar. 21, 2008, isincorporated by reference herein in its entirety. U.S. patentapplication Ser. No. 12/238,399 filed on Sep. 25, 2008, is incorporatedby reference herein in its entirety. U.S. patent application Ser. No.12/238,367 filed on Sep. 25, 2008, is incorporated by reference hereinin its entirety. U.S. patent application Ser. No. 12/238,379 filed onSep. 25, 2008, is incorporated by reference herein in its entirety.

The following detailed description and exemplary embodiments of theinvention will be best understood by reference to the accompanyingdrawings, wherein the elements and features of the invention aredesignated by numerals throughout.

In describing and claiming the present invention, the followingterminology will be used in accordance with the definitions set forthbelow.

The singular forms “a,” “an,” and, “the” include plural referents unlessthe context clearly dictates otherwise. Thus, for example, reference to“a wallboard” includes reference to one or more of such wallboards, andreference to “the binder” includes reference to one or more of suchbinders.

As used herein, “substantially” refers to situations close to andincluding 100%. Substantially is used to indicate that, though 100% isdesirable, a small deviation therefrom is acceptable. For example,substantially free of mold includes situations completely devoid ofmold, as well as situations wherein a negligible amount of mold ispresent, as determined by the particular situation.

As used herein, the term “about” is used to provide flexibility to anumerical range endpoint by providing that a given value may be “alittle above” or “a little below” the endpoint.

For purposes of discussion and interpretation of the claims as set forthherein, the terms “utility material,” “utility building material,” or“building material,” as used herein, shall be understood to mean varioustypes of products or materials incorporating a matrix of microparticles(e.g., microspheres) adhered or bound together using one or morecomponents, such as a binder of some kind and a setting agent. Thebuilding materials may comprise other additives, components, orconstituents, such as setting agents, foaming agents or surfactants,water soluble polymers, and others. The building materials may comprisemany different types, embodiments, etc., and may be used in manydifferent applications.

The term “microparticle,” as used herein, shall be understood to meanany naturally occurring, manufactured, or synthetic particle having anouter surface and an interior space such as a hollow interior.Generally, the microparticles referred to herein comprise a spherical orsubstantially spherical geometry having a hollow interior, known asmicrospheres or cenospheres.

The term “core matrix,” as used herein, shall be understood to mean thecombination of microparticles and other constituents used to form thesupport matrix of the building materials. The microparticles may becombined with one or more binders, setting agents, additives, etc. Theterms “core matrix” and “composition” may be used interchangeably in thecontext, of a utility material such as a wallboard.

The term “ambient temperature,” as used herein, shall be understood tomean the temperature of a surrounding environment when a composition orcore matrix becomes set or cured. Unless indicated otherwise, ambienttemperature ranges from about 65 degrees F. to about 80 degrees F.

The term “set composition,” as used herein, is a composition that hasbecome firm or hardened, due to a chemical change, sufficient tomaintain a substantially self-supporting shape throughout a curingprocess. A set composition has at least some cross-linking betweenpolymers. The terms “set core matrix” and “set composition” may be usedinterchangeably in the context of a utility material such as awallboard. It shall be understood that a composition or core matrix canbe set at ambient temperature, above ambient temperature, or belowambient temperature. Unless indicated otherwise, setting shall generallybe understood to occur at ambient temperature.

The term “cured composition” is a composition that is substantiallydevoid of water. The terms “cured core matrix” and “cured composition”may be used interchangeably in the context of a utility material such asa wallboard. A composition or core matrix may become cured at ambienttemperature, above ambient temperature, or below ambient temperature.Upon curing, the water content of the wallboard material may be lessthen 5%, and can be less than 1%.

The term “multi-elevational” shall be understood to describe at leastone surface of the core matrix of the building material, wherein thesurface has formed therein a series of peaks and valleys (or protrusionsand recesses) to provide an overall surface configuration havingdifferent surfaces located in different elevations and/or orientations.The multi-elevational surface configuration may be arbitrarily formed orpatterned. In addition, the multi-elevational surface may be defined byany arbitrary or geometrically shaped protruding and recessedcomponents.

As used herein, a plurality of items, structural elements, compositionalelements, and/or materials may be presented in a common list forconvenience. However, these lists should be construed as though eachmember of the list is individually identified as a separate and uniquemember. Thus, no individual member of such list should be construed as ade facto equivalent of any other member of the same list solely based ontheir presentation in a common group without indications to thecontrary.

Concentrations, amounts, and other numerical data may be expressed orpresented herein in a range format, it is to be understood that such arange format is used merely for convenience and brevity and thus shouldbe interpreted flexibly to include not only the numerical valuesexplicitly recited as the limits of the range, but also to include allthe individual numerical values or sub-ranges encompassed within thatrange as if each numerical value and sub-range is explicitly recited. Asan illustration, a numerical range of “about 1 to about 5” should beinterpreted to include not only the explicitly recited values of about 1to about 5, but also include individual values and sub-ranges within theindicated range. Thus, included in this numerical range are individualvalues such as 2, 3, and 4 and sub-ranges such as from 1-3, from 2-4,and from 3-5, etc.

This same principle applies to ranges reciting only one numerical value.Furthermore, such an interpretation should apply regardless of thebreadth of the range or the characteristics being described.

The composition of the present invention provides several significantadvantages over prior related compositions for utility materials (e.g.wallboard), some of which are recited here and throughout the followingmore detailed description. First, the present composition is capable ofrapidly setting, typically in one hour or less. Second, the setcomposition of the present invention exhibits properties desirable for autility material such as a wallboard. For example, the composition givesa wallboard properties that meet at least minimum industry standardssuch as strength, flexibility, hardness, nail pull resistance, as wellas thermal and/or acoustical properties, fire resistant properties, etc.

Each of the above-recited advantages will be apparent in light of thedetailed description set forth below, with reference to the accompanyingdrawings. These advantages are not meant to be limiting in any way.Indeed, one skilled in the art will appreciate that other advantages maybe realized, other than those specifically recited herein, uponpracticing the present invention.

The present invention describes a composition that may form part of autility material, such as a wallboard building material, castingmaterial, etc. The composition may include microparticles, an inorganicbinder, and a setting agent operable with the inorganic binder, whichallows the composition to set under ambient temperature conditions andto possess a desired property once set or cured. It should be noted,however, that the present scope includes compositions that can be set atambient temperatures, above ambient temperatures, and below ambienttemperatures. The time needed to set the composition may depend upon theweight percentages of the various constituents of the core matrix, butmay be less than or equal to one hour.

Once set, the composition may then be cured by allowing or causing theevaporation of water present within the composition. Curing mayfacilitate additional cross-linking of the binder(s) with themicroparticles. In one aspect, curing may be done at ambienttemperature, which may take between 12 and 48 hours, for example, for awallboard material having a thickness of about ½ inch. In anotheraspect, curing may be accelerated by subjecting the composition toelevated temperatures, such as by heating, for a given period of time.Thus, curing by heating is temperature dependent and is different fromcuring at ambient temperature.

Further, the present invention describes a method of manufacturing autility material, such as a wallboard building material, shear panel,casting material, etc. As mentioned above, a composition, as describedherein, may be a core matrix for a utility material. Thus, the methodcan include forming a core matrix including microparticles, an inorganicbinder, and a setting agent operable with the inorganic binder to setthe core matrix and to possess a desired property once set or cured. Thecore matrix can be deposited within a mold having any desired shape orconfiguration. The core matrix can then be allowed to set sufficient toform a set composition. Once set, the core matrix may then be cured.

The present invention also describes a method of making a wallboard orother utility material comprising the core matrix discussed herein, andhaving a setting time of less than or equal to one hour. In one aspect,a wallboard building material comprises a core matrix disposed betweenopposing facing sheets or layers, such as the type of paper common onconventional drywall-type wallboard products. In another aspect, awallboard building material comprises a core matrix disposed on a singleside of a single facing sheet, such that the wallboard has one side withan exposed core matrix face. In yet another aspect, a wallboard buildingmaterial comprises one or more facing membranes disposed within the corematrix so the core matrix is on both sides of one or more interiorfacing membranes, such that both sides of the wallboard have exposedcore matrix faces.

The microparticles contemplated for use herein may comprise manydifferent types, sizes, shapes, constituents, etc. Although not limitedto this, the microparticles used in the present invention wallboardbuilding material will generally have a size ranging between 10 and 1500microns, or between 10 and 1000 microns, and at times between 10 and 500microns. Cenospheres sized between 10 and 500 microns are readilyavailable. The bulk density of the microparticles is generally 0.4-0.6g/ml, providing products that are much lighter than conventionalwallboard building materials, such as gypsum-based drywall. The size ofthe microparticles will depend upon the application and the performancecharacteristics desired. However, the particles should not be so largeas to cause any binder disposed thereon to run off or to not beeffective. The size of the microparticles will also function toinfluence the permeability of the wallboard building material.

The microparticles are intended to be compatible with any binders,additives, and/or facing sheets. The shell thickness of themicroparticles may be kept to a minimum amount, provided themicroparticles maintain structural integrity as desired in the corematrix material. In one aspect, the microparticles can have a shellthickness of less than about 30% of diameter of the microparticle.Wherein the microparticles are not spherical, the diameter of theparticle can be calculated based on the effective diameter of theparticle, using the total area of the cross section of the particle andequating such area to a circumferential area and determining thediameter from that value. In a further embodiment, the shell thicknesscan be less than about 20% of the diameter of the microparticle.

In one exemplary embodiment, the microparticles may comprise hollow,inert, lightweight, naturally occurring, glass particles that aresubstantially spherical in geometry. One particular type is sold underthe trademark Extendospheres™, which are manufactured and sold by SphereOne Corporation. A hollow interior is preferred as this will reduce theweight of the building material, as well as provide good insulatingproperties. Furthermore, in one aspect, the microspheres ormicroparticles maintain structural integrity and retain their hollownature, or original formation to the exclusion of binder or other matrixmaterials infiltrating the hollow portions of the microparticles.

In one aspect of this embodiment, the microparticles may comprise thenaturally occurring hollow, inert, glass microspheres obtained from afly ash byproduct, which microspheres are often referred to ascenospheres. These cenospheres may be separated from the other byproductcomponents present in the fly ash and further processed, such as toclean and separate these into desired size ranges. Cenospheres arecomprised primarily of silica and alumina, and have a hollow interiorthat is filled with air and/or other gasses. They possess many desirableproperties, such as a crush strength between 3000 psi and 5000 psi, lowspecific gravity and are able to endure extremely high temperatures(above 1800 degrees F.). Although they are substantially spherical inoverall shape, many are not true spheres, as many are fragmented, orcomprise unsmooth surfaces caused by additional silica and/or alumina.

The advantage with having a synthetic material is the uniformity andconsistency between microparticles, thus making their behavior and thebehavior of the resulting core matrix and building material morepredictable. However, these advantages may not be significant enough tojustify their use, as synthetic microparticles are extremely expensiveto manufacture and can be cost prohibitive in many applications. The useof naturally occurring microparticles over synthetic ones to form abuilding material may depend on several different factors, such as theintended application, and/or the desired performance properties orcharacteristics. In some applications, naturally occurringmicroparticles may be preferred while in others a synthetic type may bemore desirable. In one aspect, however, a combination of naturallyoccurring microparticles and synthetic microparticles can be utilizedtogether in the core matrix. The combination of microparticles can be ahomogeneous or heterogeneous distribution throughout the utilitymaterial.

Microparticles or microspheres can include an amount of air or othergasses within the hollow interior. Where possible, the composition ofthe gaseous material within the microparticle can optionally be selectedso as to provide enhanced characteristics of the utility material. Forexample, the hollow interior can include an inert gas or other knowninsulating gasses to improve the insulating properties of the overallutility material. In one embodiment, a noble gas such as argon may beused.

In one specific example, a composition or core matrix can include fromabout 25 wt % to about 75 wt % of microparticles based on wetformulation. In another specific example, a composition or core matrixcan include from about 50 wt % to about 60 wt % of microparticles basedon wet formulation.

The present invention further comprises one or more binders operable tocouple together the microparticles and to facilitate formation of a corematrix. In one exemplary embodiment, the binder comprises an inorganicbinder, such as sodium silicates in one form or another. This may or maynot be combined with an organic binder such as polyvinyl acetatecopolymer or ethylene vinyl acetate. A vinyl acetate copolymer may beused, for example, to increase water resistance of a wallboard.

In one specific example, a composition can include from about 20 wt % toabout 60 wt % of sodium silicate binder based on wet formulation. Inanother specific example, a composition can include from about 35 wt %to about 45 wt % of sodium silicate binder based on wet formulation.

In many cases, the inorganic binder solution may comprise a ratio ofsodium silicate to water of from about 1:2 to about 2:1, although,higher water content may necessitate a longer curing time. In oneembodiment, the ratio of sodium silicate to water is 1:1. The sodiumsilicate may be pre-mixed and the solution provided in liquid form, orthe sodium silicate may be in powder form and subsequently mixed withwater.

The present invention further contemplates one or more constituents ofthe core matrix comprising a setting agent operable with the one or morehinders to cause or enable the core matrix composition to initially setor harden under ambient temperature conditions. In other words, it iscontemplated that one or more setting agents may be present within thecore matrix composition that will result in a set or hardened corematrix, wherein at least a portion of the setting agent reacts toprovide at least some cross linking that gives some structural integrityto the core matrix.

The present invention further comprises a setting agent operable tocause a composition or core matrix to set at a variety of temperatures,including ambient temperature. In one aspect, the setting agent cancause the composition to set in one hour or less. In one embodiment, asetting agent may be an isocyanate material. In a specific embodiment,the isocyanate material may be polymeric. In another aspect, theisocyanate material may be prepolymeric. A prepolymeric isocyanate is anisocyanate polymer chain having a reactive isocyanate terminal group. Inone example, isocyanate molecular weight may be from about 1000 to about8000. In another example, isocyanate molecular weight may be from about2000 to about 5000.

Using a suitable setting agent such as isocyanate, the core matrixcomposition does not need to be subjected to elevated temperatures toeffectuate initial setting or hardening, and may be cured to produce asuitable end product utility material that will possess the physical andperformance properties desired for the particular type of utilitymaterial being manufactured.

In a specific example, isocyanate setting agent can be present in anamount from about 2% by weight to about 10% by weight of the totalweight of the core matrix in wet mixture. In another specific example,isocyanate setting agent can be present in an amount from about 3% byweight to about 6% by weight of the total weight of the core matrix inwet mixture.

The ratio of binder to setting agent may range between 1:1 and 15:1, andtypically between 8:1 and 12:1, depending upon the desiredcharacteristics of the core matrix. Obviously, these ratios may bevaried to vary the characteristics of the core matrix. For example, toincrease the strength and other characteristics of a utility material,the core matrix may comprise a lower ratio of binder to setting agent(e.g., between 5:1 and 7:1).

The ratio of binder to microparticles may vary depending upon thebuilding material to be formed. A higher ratio of binder tomicroparticles will result in a building material that is more solid anddense than one with a smaller ratio. Indeed, a smaller ratio of binderto microparticles will result in a more porous building material.

The core matrix may further comprise a setting agent in addition toisocyanate, configured or intended to enhance the water resistantproperties of the building material, and particularly the core matrix ofthe building material. In one exemplary embodiment, the setting agentmay comprise Class C fly ash. In another exemplary embodiment, thesetting agent may comprise zinc oxide. In still another exemplaryembodiment, the setting agent may comprise sodium fluorosilicate. Thus,Class C fly ash, zinc oxide, or sodium fluorosilicate may be used, forexample, to increase water resistance of a wallboard.

The core matrix may further comprise one or more additives or fillers.Alternatively, the core matrix may be devoid of further additives and/orfillers. When present, these may be present in an amount between 0.01and 50% by weight of the total weight of the core matrix in wet mixture.In one exemplary embodiment, the microparticles may be blended withexpanded siliceous inorganic particles, such as perlite, to lower thedensity of the building material, decrease its weight, and reducemanufacturing costs. Specifically, it is contemplated that expandedsiliceous inorganic particles may replace a portion of microparticles inan amount between 1% and 50% by weight of the total weight of the corematrix in wet mixture.

It should be noted that fly ash, of any type, can be utilized as afiller material, and/or optionally as a source of cenospheres. In oneaspect, Class C fly ash can be one or the only source of microparticles.Class C fly ash can, in one aspect, be included in a core matrix in anamount ranging from about 0.5 wt % to about 50 wt %, in wet mixtureform. In one aspect, it can be present in combination with syntheticallymade microparticles at a ratio of Class C fly ash to syntheticmicroparticles of about 1:15 to about 15:1. In a further embodiment,Class C fly ash can be present in an amount of less than about ⅓ of theamount of microparticles. The Class C fly ash used can optionallyinclude greater than about 80 wt % calcium aluminum silicates, and lessthan 2 wt % lime.

Without intending to be bound by any scientific theory, it is believedthat upon mixing polymeric isocyanate with sodium silicate in water, achemical reaction occurs that sets the composition and liberates CO₂.The chemical reaction can also cause cross-linking to occur in thecomposition. It is believed that this cross-linking may be a result ofthe liberation of CO₂. Thus, in one aspect of the present invention,polymeric cross-linking can occur during setting.

By cross-linking the binder(s), a stronger more permanent physicalcoupling occurs among the binder, thus better physically securing themicrospheres. As such, the present invention contemplates using one ormore means to effectively cross-link the binders. In one exemplaryembodiment, the binders may be cross-linked by setting the core matrix.In another exemplary embodiment, the binders may be cross-linked bycuring the core matrix. It should be noted that this cross-linkingduring curing procedure is in addition to cross-linking that occursduring setting. In another exemplary embodiment, the binders may becross-linked by elevating the temperatures of the binders to a suitabletemperature for a suitable period of time to effectuate, polymerizationand bonding. This may be done using conventional radiant heatingmethods, or it may be done using microwaves applied continuously or atvarious intervals, as well as with microwaves of different intensities.Depending on the binders used, it may be useful to add a limited amountof cross-linking agent to the binder formula in order to increase and/orcontrol the cross-linking.

Cross-linking within a building material provides significant advantagesover a building material having a composition that is not cross-linked.For example, with cross-linking, the binders are generally stronger,they do not absorb water as easily, and the connection betweenmicroparticles is much stronger. In addition, the building material doesnot weaken over time. Other advantages may be realized by those skilledin the art. Having said this though, there may be applications wherecross-linking is not preferred, and where a non-bonded composition isbetter suited. This, of course, is contemplated herein.

Curing may facilitate additional polymerization, or cross-linking,beyond what occurred during setting. Curing of the core matrix may beactive or passive. Active curing may be subjecting a composition or corematrix to elevated temperatures such as by heating. Passive curing mayinvolve allowing a composition or core matrix to cure for a period oftime without significant heating. Acceptable temperatures for curing maydepend upon the material of the facing membranes. For example, an uppertemperature may be limited by the facing membrane material to preventdamage to the material. In one embodiment, a facing membrane materialmay comprise paper. In this embodiment, a possible temperature forcuring may range from between ambient temperature to about 400 degreesF. A useful temperature for curing, in this embodiment, may range fromabout ambient temperature to about 300 degrees F. A lower heatingtemperature, for example, may be about 125 degrees F., with a typicalrange being from about 150 degrees F. to about 300 degrees F.

As noted, a variety of methods can be useful in forming utilitymaterials as presently contemplated. In one aspect, a method of forminga wallboard utility material can include first placing a precut facingsheet, such as a wallboard paper white, face down in an appropriatemold. A formable composition can be formed by mixing microparticles,binder, and the setting agent. The formable composition can be spreadover the paper in the mold and can be smoothed using any method. Asecond facing sheet, such as a brown wallboard paper, can be placed overthe mixture. A flat mold lid can be placed on top of the paper andfastened in place. At this point, the core matrix composition may beallowed to initially set via the setting agent. To effectuate curing,the resulting wallboard product can optionally be subjected to elevatedtemperatures for a given period of time, such as by heating, or it maybe allowed to cure under ambient temperature conditions, although thismay take longer. Heat curing can occur at temperatures greater thanambient temperature, preferably less than temperatures required to causedamage or degradation of the paper, mold, or components of the formablecomposition.

In one aspect, all components for the core matrix can be mixed togetherin a single step or in multiple separate steps in separate mixers. Avariety of mixers can be utilized. In a specific embodiment, an augercan be utilized to mix the components for the core matrix. The mixturecan be poured into a mold lined with a facing membrane, i.e. paper oraluminum, etc. The mold can be placed on a vibrating table so as toencourage proper spread of the mixture onto the membrane. Various othermethods are known in the art to properly spread the mixture onto themembrane and are likewise contemplated herein. The second facingmembrane can be placed on top of the leveled mixture and the mold canoptionally be removed from the green or uncured wallboard. The greenwallboard can then be positioned to effectuate initial setting orhardening of the core matrix. Once set, the green wallboard can then befurther cured (e.g., such as being placed in an oven). This process canoccur in batch, semi-batch, or continuous design.

In a continuous flow, a conveyor can move the green wallboard to andthrough an oven. Optionally, leveling rollers can be utilized tomaintain the desired planar shape and thickness of the wallboard duringdrying. In one aspect, the presence of a metallic facing membrane canallow the method to include exposing the wallboard material to atemperature sufficient to effectuate even more rapid drying and curingof the core matrix. The parameters recited above can be appropriatelymodified for equipment, variations in core matrix composition, facingmembrane types, etc. In the case of batch formation, individualwallboard can be formed and placed in a multi-rack drying oven.Temperature profiles for the oven rack can range depending on thecomposition of the core matrix and the facing sheets used.

As noted, a method of forming a wallboard material can include forming acore matrix including mixture of microparticles, sodium silicate binder,and an isocyanate setting agent. This may be followed by disposing thecore matrix mixture between a first facing membrane and a second facingmembrane and then setting the core matrix. In one aspect of the presentinvention, forming the core matrix may comprise forming a first mixtureincluding microparticles and sodium silicate binder and forming a secondmixture including microparticles and the isocyanate setting agent. Thismay be followed by mixing the first mixture with the second mixture toform the core matrix. In another aspect, the method may further includecoating a contact surface of at least one of the facing membranes with asodium silicate coating prior to disposing the core matrix between them.In another aspect, a wallboard building material comprises a core matrixdisposed on a single side of a single facing sheet, such that thewallboard has one side with an exposed core matrix face. In yet anotheraspect, a wallboard building material comprises one or more facingmembranes disposed within the core matrix so that the core matrix is onboth sides of one or more interior facing membranes, such that thewallboard has two sides with exposed core matrix faces.

Once a core matrix is disposed on a facing membrane or between facingmembranes, the core matrix can then be permitted to set or harden undernormal ambient temperatures sufficient to form a wallboard materialhaving the metallic facing membrane and the second facing membraneattached, adhered, bonded, or otherwise secured to the formed corematrix. The setting or hardening time may be completed in one hour orless, 30 minutes or less, or in 15 minutes or less, with curing (eitherunder ambient temperature conditions or elevated temperature conditionsif accelerated drying is desired) taking place thereafter to facilitateevaporation of water present within the core matrix and cross-linking ofthe binder(s) with the microparticles.

In one aspect, the method can be free from additional steps in-betweenthe deposition, and setting steps; meaning, the components may be mixed,including water, immediately deposited between facing membranes, andimmediately caused to set or harden. In one aspect, the wallboard can becut before and/or after setting and curing. In a further aspect, one ormore leveling rollers can be utilized prior to or during the settingand/or curing steps to maintain a desired shape and level to thewallboard.

In a semi-rigid, molded state, the microparticles, setting agent,binder, and any other components are pre-mixed together in such a way soas to form a semi-rigid utility material. The microparticles are causedto dry or harden, as well as to bond via the binder, in one aspect, thepre-mixed composition may then be placed into a mold and formed into adesired size and shape in accordance with one or more molding methods,examples of which are described below.

In another aspect, the pre-mixed composition may be deposited ordisposed onto a surface, such as a moving conveyor, and then cut orotherwise formed into the desired size and shape, either before or afterthe setting and/or curing steps.

The utility materials formed to comprise a semi-rigid makeup may beformed into panels of different size, shape, and thickness, such aspanels that function as and that have physical characteristicscomparable to conventional wallboard. Various backing or containingmembers may be utilized to support or provide a barrier to thecomposition. The density of the wallboard building material having thecore composition just described can be between 0.4 g/ml and 0.6 g/ml.

With reference to FIGS. 1 and 2, illustrated is a general perspectiveview and a detailed perspective view, respectively, of a wallboardbuilding material in accordance with one exemplary embodiment of thepresent invention. As shown, the wallboard building material 10 is inpanel form having a size of approximately 4 ft, in width, and 8 ft. inlength, and approximately ½ inch thick, which is the same size as mostconventional wallboard products. Of course, other sizes such 4 ft. by 12ft. sizes, as well as different thicknesses is also contemplated. Thewallboard building material 10 is shown as comprising a core matrix 14disposed between opposing facing sheets or layers, namely first facingmembrane 34 and second facing membrane 54. Of course, the wallboardbuilding material may comprise a single facing membrane, having one sideexposed as discussed above. Each of the first facing membrane 34 and thesecond facing membrane 54 may have a contact surface in contact with thecore matrix 14. A contact surface may be any portion of a surface, or anentire surface, of a facing membrane. Before a core matrix 14 isdisposed between opposing facing membranes (or on at least one facingmembrane), a contact surface of a facing membrane may be designated as asurface that will come into contact with the core matrix, including anindividual component or sub-mixture of select core matrix components,during the process of making a wallboard. For example, a contact surfaceof a facing membrane may be coated with a sodium silicate coating priorto disposing the core matrix between facing membranes. In anotherexample, a contact surface of a facing membrane may be coated with asub-mixture of microparticles and sodium silicate binder or coated witha sub-mixture of microparticles and isocyanate setting agent, during theprocess of making a wallboard.

The core matrix 14 is comprised primarily of a plurality ofmicroparticles, at least one binder and a setting agent (isocyanatesetting agent) operable with the at least one binder, wherein themicroparticles are at least bound or adhered together, and preferablybonded together, by the one or more binders and the setting agent tocreate a core matrix structure having a plurality of voids definedtherein. The voids are formed from the point to point contact betweenthe microparticles.

With reference to FIG. 3, the wallboard building material may furthercomprise a reinforcing member operable with the core matrix configuredto provide enhanced characteristics in one or more areas as comparedwith the exemplary wallboard building material of FIGS. 1 and 2. In theexemplary embodiment shown, the wallboard 110 comprises similarcomponents as discussed above with respect to the wallboard 10 of FIGS.1 and 2, only the wallboard 110 comprises an additional reinforcingmember 174 disposed within the core matrix 114 (sandwiched therein).Reinforcing member 174 is configured to reinforce or enhance one or moreproperties or characteristics of the wallboard 110. For example, thereinforcing member 174 may be configured to reinforce against (orimprove the resistance of) sound transmission, heat transfer or acombination of these. The reinforcing member 174 may also be configuredto enhance the overall strength of the wallboard building material 110.

The reinforcing member 174 may comprise various types of materials, suchas metals, woven or nonwoven fibers or fiber sheets, plastic films,etc., and may comprise any necessary thickness. In the exemplaryembodiment shown, the reinforcing member 174 comprises an aluminummaterial disposed within the core matrix.

With reference to FIG. 4, illustrated is a wallboard building material10, formed in accordance with one exemplary embodiment of the presentinvention, just prior to being installed on or hung from a stud wall 2.Specifically, wallboard building material 10 comprises the samecomponents as that of FIGS. 1 and 2. It should be noted that nospecialized installation techniques are required for installing orhanging the wallboard building material 10. The wallboard buildingmaterial 10 may be installed in a similar manner as conventional drywallor other similar products. However, FIGS. 5-A and 5-B illustrate otherexemplary embodiments of wallboard building materials that may requireone or more special installation techniques. These embodiments arediscussed in detail below.

With reference to FIGS. 5-A and 5-B, illustrated are two differentexamples of coupling and sealing systems, each one being incorporatedinto a present invention wallboard building material, and each one beingconfigured to couple adjacent wallboard panels together, and to seal orat least partially seal (e.g., not necessarily a strictly airtight seal)the adjacent wallboard panels. The coupling and sealing system isintended to reduce and/or eliminate the flanking path between theadjacent wallboard panels at the joint. The seal may be further enhancedor improved upon nailing, screwing, or otherwise securing the joint to astud in a stud wall. Indeed, the overlap shown is intended to bepositioned about a stud, but this may or may not always be possible. Theseal functions to resist sound transmission through the joint, and alsoto resist heat transfer through the joint, by creating a more complexflanking path for heat transfer and sound transmission. In other words,the flanking path is intended to be reduced and/or eliminated ifpossible by the coupling and sealing system of the present invention.

With specific reference to FIG. 5-A, illustrated are partial end viewsof a first wallboard building material 210-A and a second wallboardbuilding material 210-B, each one formed in a manner as describedherein. The first wallboard building material 210-A comprises aprotruding or male configuration 218 formed within and along an edge ofthe core matrix 214-A, which is intended to align and mate with acorresponding recess or female configuration 222 formed within and alongan edge of the core matrix 214-B of the second wallboard buildingmaterial 210-B. The coupling or connection is designed to secure thefirst and second wallboard building materials 210-A and 210-B,respectively, in a proper position with respect to one another, and topermit the edges of the membranes 234-A and 254-A of the first wallboardbuilding material 210-A to meet the membranes 234-B and 254-B of thesecond wallboard building material 210-B. The coupling system furtherhelps to maintain proper positioning after installation. The couplingsystem may be formed about any of the edges of the wallboard buildingmaterial.

FIG. 5-B illustrates partial end views of a first wallboard buildingmaterial 310-A and a second wallboard building material 310-B each oneformed in a manner as described herein. The first wallboard buildingmaterial 310-A comprises a notch 326 formed within and along an edge ofthe core matrix 314-A, with the surface parallel to the surface of themembranes 334-A and 354-A optionally comprising a nub 328, also formedfrom the core matrix 314-A. The notch 326 is intended to align and matewith a corresponding notch 330 formed in the second wallboard buildingmaterial 310-B to couple together the first and second wallboardbuilding materials. The notch 326 optionally comprises a recess 332 thatreceives nub 328 therein when the first and second wallboard buildingmaterials are secured or coupled to one another. The coupling systemshown in FIG. 5-B is intended to perform a similar function as thecoupling system shown in FIG. 5-A.

It is noted that the coupling system is integrally formed into the corematrix during manufacture of the wallboard building material. The uniquecomposition of the core matrix provides this capability. The particularsize, shape, or configuration of the coupling system may vary, and maybe formed in accordance with various different manufacturing techniques.

It also contemplated that one or more sealing members or adhesives maybe applied to the coupling system to enhance the sealing functionachieved by coupling the two wallboard panels together.

With reference to FIG. 6, illustrated is a detailed perspective view ofa wallboard building material formed in accordance with one exemplaryembodiment of the present invention.

Utility materials can exist in a variety of forms. Much discussionherein is directed to the specific embodiment of wallboard. However, itshould be noted that the principles, compositions, and methods discussedapply to a variety of forms of utility materials, and should beinterpreted as such.

As shown in FIG. 6, the building material 710 is in panel form, similarto a wallboard panel, having a size of approximately 4 ft. in width, and8 ft. in length, which is the same size as most conventional wallboardproducts. Of course, other sizes such 4 ft. by 8 ft. sizes, as well asdifferent thicknesses is also contemplated. The building material 710 isshown as comprising a core matrix 714 disposed about a single facingsheet or layer, namely facing membrane 734. The other side 718 of thebuilding material 710 is exposed, or rather, the other side of the corematrix 714 is exposed, thus exposing a portion of the configuration ofmicroparticles, binder and setting agent. The exposed surface of thecore matrix provides and defines a rough, porous surface that isdesigned and intended to better attenuate sound. The exposed side 718 ofthe core matrix 714 is intended to face inward as the building materialis installed or mounted to a structure, such as a stud all with thefacing membrane 734 facing out.

The density of the building material having the core composition justdescribed is generally between 0.4 g/ml and 0.6 g/ml, although suchdensity can vary greatly depending on the selection and amount of eachcomponent, as well as the presence or absence of foaming.

The facing membrane 34, and/or 54 shown in FIG. 2, may comprise manydifferent types of materials or combination of materials, and maycomprise different properties. In one exemplary embodiment, facingmembranes 34 and/or 54 can each be independently selected. One or bothfacing membranes can comprises a paper material similar to that found onvarious wallboard products, such as drywall or the wallboardincorporated by reference herein, as noted above. In another exemplaryembodiment, the facing membrane may comprise metal or a metal alloy. Themetal may be quilted, corrugated or otherwise comprise one or morenonplanar surface configurations. In a further embodiment, one facingmembrane can comprise or consist essentially of aluminum or quiltedaluminum. In such cases, the aluminum may have a thickness ranging fromabout 0.002 in, to about 0.010 in, and more commonly between 0.004 in.and 0.005 in. Optionally, the metallic facing membrane, e.g. an aluminumfacing membrane, can be embossed or otherwise include athree-dimensional pattern on the surface, or throughout the entirelength of the membrane.

As the final product is desirably a cohesive one, in one aspect, thecore material and facing sheet of the wallboard can be optimized forproper or superior adhesion, thus ensuring the facing sheet will remainsecured to the core material. As such, additional binder or binders atthe surface level can be utilized to improve adhesion of a facing sheetto the core matrix. Alternatively, a different adhesive agent can beutilized to improve adhesion of a facing sheet to the core matrix.

In certain applications, it may be desirable to eliminate the facingsheet altogether. Specifically, to enhance the fire resistant propertiesof the building material, the facing sheet, particularly if paper, maybe eliminated. The core matrix may be configured to be self-supporting,meaning that the building material does not require a facing sheet tomaintain its shape and integrity.

FIG. 6 further illustrates the exposed side 718 of the core matrix ascomprising a multi-elevational surface configuration. Such aconfiguration may be utilized to reduce weight. Additionally, thisconfiguration may be designed in such a way that enhances the soundattenuation properties of the building material. The purpose ofproviding a multi-elevational surface configuration formed about onesurface, particularly the exposed surface, of the core matrix is atleast threefold—1) to reduce weight, 2) to enhance the sound attenuationor damping properties of the building material, namely to ensureacoustic isolation and absorption over a wide range of frequencies, and3) to enhance the flex strength of the building material by eliminatingshear lines. As will be described below, many differentmulti-elevational surface configurations are contemplated herein. Thoseskilled in the art will recognize the benefits of providing a series ofpeaks and valleys about a surface to create different surfaces locatedin different elevations, as well as different surfaces oriented ondifferent inclines, particularly for the specific purpose of attenuatingsound. Sound waves incident on these different elevational and/ororiented surfaces are more effectively attenuated.

In the specific embodiment shown, the multi-elevational surfaceconfiguration comprises a waffle pattern, with a plurality of protrudingmembers 718, having a square or rectangular cross-section, defining aplurality of recesses 726. This series of peaks and valleys effectivelycreates a plurality of surfaces (in this case horizontal surfaces 730and 734) that are located in different elevations about the overallsurface of the core matrix 714. In addition, the protruding members 718may be configured to provide surfaces oriented at different angles (inthis case, the protruding members 718 also define several verticallyoriented surfaces 738).

It is further contemplated that a separate mesh facing sheet may or maynot be disposed over the exposed multi-elevational surface of the corematrix 714. If used, the mesh facing sheet is preferably configured tobe flexible to conform to the multi-elevational surface configuration.The mesh facing sheet may be made from glass, plastics (e.g., extrudedplastics), or other materials, depending upon the particular applicationand need.

FIGS. 6 and 14 further illustrate the building material 710 ascomprising a plurality of cavities or air pockets 746 strategicallyformed and located throughout the core matrix 714, and designed toreduce the overall weight of the building material without significantlyaffecting the strength or other properties of the building material.Preferably, the cavities 746 are randomly located throughout the corematrix 714, but they may also be arranged in a pre-determined pattern.The cavities 746 may be formed during the manufacture of the buildingmaterial. Essentially, the cavities 746 function to define a pluralityof voids or air pockets within the core matrix 714 at various locations.The cavities 746 may be sized to comprise a volume between about 0.2 andabout 200 cm³, and preferably between about 5 and about 130 cm³. Thesenot only help to reduce weight, but also help to increase the overall Rvalue due to the dead air space. In addition, these help to furtherattenuate sound as these provide additional surfaces that function toabsorb sound waves rather than transmit them.

With reference to FIGS. 7-A and 7-B, shown is a building material formedin accordance with another exemplary embodiment of the presentinvention. The building material 810 is similar in many respects to thebuilding material 810 discussed above and shown in FIG. 6. However,building material 810 comprises a lath 854 disposed or sandwiched withinthe core matrix 814. The lath 854 comprises a plurality of intersectingmembers 856 forming a grid having a plurality of openings 858. The lath854 functions to provide support and stability to the core matrix 814,as well as additional strength. In addition, the lath 854 increases themass of the building material 810, which reduces the potential forvibration, thus contributing to the sound attenuation properties of thebuilding material 810. The lath 854 may comprise many different typesand configurations, with the grid and openings being of different sizesand configurations. The lath 854 shown in FIG. 7 is not intended to belimiting in any way.

In one aspect, the lath 854 may comprise a metal, fiberglass, or plasticmesh or mesh-like material. This reinforcing lath material providesstrength to the building material 810, and further supports themicroparticles. The lath 854 may also be made from glass, plastics(e.g., extruded plastics), or other materials, depending upon theparticular application and need.

With reference to FIGS. 8-10, illustrated is a building material 910formed in accordance with another exemplary embodiment of the presentinvention. In this embodiment, the building material 910 comprises acore matrix 914 having a first surface 918. Formed in the first surface918 is a multi-elevational or nonplanar surface configuration in theform of a repeating pattern of pillow-type protrusions, thus providingmultiple different surfaces or surface area in multiple differentelevations. The protrusions may be any desired size, configuration, andheight. Therefore, those shown in the drawings are intended to be merelyexemplary.

With reference to FIG. 11, illustrated is a side view of the buildingmaterial 710 of FIG. 6, having a multi-elevational surface configurationin the form of a repeating waffle-type pattern. The waffle-typeconfiguration extends between the perimeter edges of the buildingmaterial, and defines a plurality of protrusions 722 and recesses 726.FIG. 9 illustrates a cross-sectional view of a building material whereinthe building material 710 comprises a plurality of strategically formedand located cavities or voids 746 in the core matrix 714.

FIG. 12 illustrates a detailed side view of another exemplary buildingmaterial 1010 comprising a core matrix 1014 having a first surface 1018,wherein the first surface 1018 has formed therein a multi-elevationalsurface configuration comprising a repeating pattern of firstprotrusions 1022 in the form of pyramids or cones, and a repeatingpattern of second protrusions 1024 having an arbitrary shape. The secondprotrusions 1024 are shown as comprising a primary base protrusionhaving a square cross-section, upper secondary protrusions 1023, andlateral secondary protrusions 1025, each having a pyramid or cone shape.First and second protrusions 1022 and 1024 define recesses 1026. Whilethe present invention is not intended to be limited to any particularshape of protrusions, FIG. 12 illustrates that arbitrary shapes are atleast contemplated.

FIG. 13 illustrates a detailed side view of another exemplary buildingmaterial 1110 comprising a core matrix 1114 having a first surface 1118,wherein the first surface 1118 has formed therein a multi-elevationalsurface configuration comprising a repeating pattern of firstprotrusions 1122 and recesses 1126, wherein these form an egg cartontype pattern.

FIGS. 8-13 illustrate several different multi-elevational surfaceconfigurations. These, however, are not meant to be limiting in any way.Indeed, one skilled in the art will recognize other configurationsand/or patterns that may be used to accomplish the designs of thepresent invention.

Referring now to FIG. 15, illustrated is a building material formed inaccordance with another exemplary embodiment. In this particularembodiment, the building material 1210 comprises a core matrix 1214, ametal lath 1254 disposed or sandwiched within the core matrix 1214, anda facing sheet 1234 comprised of tar paper. With this configuration, thebuilding material 1210 may be used as a finishing material on theexterior of residential or commercial structures, replacing stucco. Thebuilding material 1210, comprising preformed panels, can be mounted orsecured to the exterior walls 1202 of a structure, say a residentialhome, much in the same way a wallboard is mounted or secured to theinterior walls of a home. Once secured in place, a stucco finish 1204commonly known in the art may be applied to the panels to create afinished look. The stucco finish can be applied so as to sufficientlyconceal any seams or gaps between adjacent building material panels.Some obvious advantages that result from providing exterior finishingpanels is the elimination of the labor intensive task of securing metallath to the exterior walls, subsequently applying plaster over the metallath, and then waiting several days for the plaster to dry and set priorto being able to apply the stucco finish. With the pre-formed buildingpanels shown herein, installers can mount the panels and apply thestucco finish immediately, thus significantly reducing labor and costs.

It is contemplated that such a building material may be applied to shearpanels, such as oriented strand board, to shear panels formed after themanner of the present invention, or directly to a stud frame, whereinthe building panel may function as the shear panel and also receive thestucco finish directly thereto, thus eliminating the need for a separateshear panel.

When the metal facing sheet is used, the heating elements can beconfigured to concentrate a majority of the heat through the metalfacing sheet to the core matrix. In this manner, the heat is betterreceived into the core matrix, steam is removed from the core matrixprimarily through the second facing sheet, typically paper, and largesteam pockets are not formed.

Utility materials as described herein exhibit superior qualities to manyutility materials currently available. Furthermore, the superiorqualities co-exist, where a material may exhibit both mold resistanceand enhanced acoustic properties simultaneously. Wallboards formed ofthe utility materials are typically lighter than conventional gypsumwallboard by 20% to 30%. An installed R value can be up to about 19.Noise attenuation can be up to about 50 db, depending on the frequencyfor a ½ inch thick piece of wallboard. The core matrix will not growmold. Wallboard is water resistant and is still hard after 2 weeks ofcontinuous submersion under water. The material can be formulated to befire resistant. Wallboard exhibits strong flexural strength up to twotimes that of conventional gypsum wallboard (e.g., 280 lbs vs. 140 lbs).Furthermore, the wallboard can withstand impacts without crumbling ordisplacement in surrounding areas such as a corner. Various industryconsiderations for wallboard performance include, but are not limitedto, surface finish, snap and dust, flexural strength, nail pullresistance, dimpling, edge crush, weight, mold growth, water resistance,fire resistance, and R value.

EXAMPLES

The following examples illustrate embodiments of the invention that arepresently known. Thus, these examples should not be considered aslimitations of the present invention, but are merely in place to teachhow to make the best-known compositions and forms of the presentinvention based upon current experimental data. Additionally, someexperimental test data is included herein to offer guidance inoptimizing compositions and forms of the utility material. As such, arepresentative number of compositions and their method of manufactureare disclosed herein.

Example 1—Sample Wallboard Utility Material

In one specific example (producing a sample core matrix havingdimensions of 8″×9″×½″), the core matrix composition is as follows: themicroparticles is 56 wt % of wet core matrix, the sodium silicate binderis 40 wt % of wet core matrix, and the isocyanate setting agent is 4 wt% of wet core matrix. In this example, the core matrix is formulated tocomprise a two-part mixture. The first part comprising 150 gramsmicroparticles initially mixed with 140 grams sodium silicate Type Ofrom PQ Corporation. The second part comprising 50 grams microparticles(e.g., cenospheres) initially mixed with 14 grams “A” side fromReactamine JS 2:1 of Reactamine Technology, LLC, which is an isocyanateprepolymer. These two mixtures, once each individually blended, werethen blended together and deposited onto one side of a sodiumsilicate-coated wallboard face paper. A waffle pattern was then pressedinto the upper surface of the core matrix composition. A second sodiumsilicate-coated paper facing sheet was then deposited over the corematrix composition, which second paper facing sheet was held in placeunder pressure for between 5-10 minutes, which allowed the core matrixcomposition to initially set and harden under ambient temperatureconditions. The sample was then placed onto a drying rack and allowed tocure under ambient temperature conditions for a 24 hour period.

The foregoing detailed description describes the invention withreference to specific exemplary embodiments. However, it will beappreciated that various modifications and changes can be made withoutdeparting from the scope of the present invention as set forth in theappended claims. The detailed description and accompanying drawings areto be regarded as merely illustrative, rather than as restrictive, andall such modifications or changes, if any, are intended to fall withinthe scope of the present invention as described and set forth herein.

More specifically, while illustrative exemplary embodiments of theinvention have been described herein, the present invention is notlimited to these embodiments, but includes any and all embodimentshaving modifications, omissions, combinations (e.g., of aspects acrossvarious embodiments), adaptations and/or alterations as would beappreciated by those in the art based on the foregoing detaileddescription. The limitations in the claims are to be interpreted broadlybased on the language employed in the claims and not limited to examplesdescribed in the foregoing detailed description or during theprosecution of the application, which examples are to be construed asnon-exclusive. For example, in the present disclosure, the term“preferably” is non-exclusive where it is intended to mean “preferably,but not limited to.” Any steps recited in any method or process claimsmay be executed in any order and are not limited to the order presentedin the claims. Means-plus-function or step-plus-function limitationswill only be employed where for a specific claim limitation all of thefollowing conditions are present in that limitation: of “means for” or“step for” is expressly recited; and b) a corresponding function isexpressly recited. The structure, material, or acts that support themeans-plus function are expressly recited in the description herein.Accordingly, the scope of the invention should be determined solely bythe appended claims and their legal equivalents, rather than by thedescriptions and examples given above.

What is claimed and desired to be secured by Letters Patent is:
 1. Autility material comprising: a wallboard having a first facing membraneand a second facing membrane; and a core matrix disposed between thefirst facing membrane and the second facing membrane, wherein the corematrix includes: a plurality of microspheres having an outer shell and ahollow interior, an inorganic binder, and a setting agent, wherein theouter shell of the microspheres excludes the inorganic binder and thesetting agent from the hollow interior of the microspheres; wherein thehollow interior of the microspheres is filled with a gas; and whereinthe microspheres are from about 10 microns to about 1500 microns insize.
 2. The utility material of claim 1, wherein the inorganic binderis a sodium silicate binder and the setting agent is an isocyanatesetting agent.
 3. The utility material of claim 2, wherein the sodiumsilicate binder and the isocyanate setting agent are at a ratio of fromabout 1:1 to about 15:1.
 4. The utility material of claim 2, wherein thesodium silicate binder and the isocyanate setting agent are at a ratioof from about 8:1 to about 12:1.
 5. The utility material of claim 1,wherein the utility material has a density between 0.4 g/ml and 0.6g/ml.
 6. The utility material of claim 1, wherein the microspheres arefrom about 10 microns to about 1000 microns in size.
 7. The utilitymaterial of claim 1, wherein the microspheres are from about 10 micronsto about 500 microns in size.
 8. The utility material of claim 1,wherein the core matrix, as a wet formulation, included from about 25 wt% to about 75 wt % of microspheres.
 9. The utility material of claim 1,wherein the core matrix, as a wet formulation, included from about 50 wt% to about 60 wt % of microspheres.
 10. The utility material of claim 1,wherein the core matrix further includes an organic binder.
 11. Theutility material of claim 10 wherein the organic binder is selected fromone of polyvinyl acetate copolymer or ethylene vinyl acetate.
 12. Theutility material of claim 2, wherein the core matrix, as a wetformulation, included from about 20 wt % to about 60 wt % of sodiumsilicate binder.
 13. The utility material of claim 2, wherein the corematrix, as a wet formulation, included from about 35 wt % to about 45 wt% of sodium silicate binder.
 14. The utility material of claim 1,wherein a reinforcing member is disposed within the core matrix.
 15. Theutility material of claim 1, wherein the core matrix comprises aprotruding configuration formed within and along an edge of the corematrix.
 16. The utility material of claim 1, wherein the core matrixcomprises a recess formed within and along an edge of the core matrix.17. The utility material of claim 1, wherein the core matrix comprises anotch and a nub formed within and along an edge of the core matrix. 18.The utility material of claim 2, wherein the core matrix, as a wetformulation, included from about 2 wt % to about 10 wt % of theisocyanate setting agent.
 19. The utility material of claim 2, whereinthe core matrix, as a wet formulation, included from about 3 wt % toabout 6 wt % of the isocyanate setting agent.